Modeling proton exchange membrane fuel cells with fiber-based microporous layers

•A two-phase multi-physics model for PEMFCs with fiber-based MPL is developed.•Fiber-based MPL enables better water removal capability and oxygen transport capability, resulting in lower liquid water saturation and higher oxygen concentration.•Effects of different fMPL structural parameters were num...

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Bibliographic Details
Published in:International journal of heat and mass transfer 2022-12, Vol.198, p.123398, Article 123398
Main Authors: Lin, P.Z., Sun, J., Shao, M.H., Wu, M.C., Zhao, T.S.
Format: Article
Language:English
Subjects:
Electrospun carbon fibers
Microporous layer
Proton exchange membrane fuel cell
Two-phase model
Water management
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Summary:•A two-phase multi-physics model for PEMFCs with fiber-based MPL is developed.•Fiber-based MPL enables better water removal capability and oxygen transport capability, resulting in lower liquid water saturation and higher oxygen concentration.•Effects of different fMPL structural parameters were numerically investigated and optimized. Microporous layers (MPLs) play a crucial role in improving water management in proton exchange membrane fuel cells (PEMFCs). Highly tunable electrospun carbon fibers offer a promising candidate for MPLs to facilitate two-phase water and gas transport in PEMFCs. In this work, we present a two-phase PEMFC model to investigate the mass transport characteristics with MPLs made of nano-/micro-fibers. Simulations were validated by the reported experimental results. It is revealed that the fiber-based MPLs (fMPLs) reduce the liquid water saturation at the cathode side due to the higher permeability, thus significantly reducing the oxygen transport resistance and resulting in superior cell performance than conventional MPLs (cMPLs) do. Moreover, PEMFCs with fMPLs outperform those with cMPLs under a wide range of operating temperatures from 40 to 80 °C. In addition, our parametric study results suggest that fMPLs with a high porosity (> 0.5), a large fiber diameter (> 2 µm), and a large contact angle (> 135°) can effectively boost water drainage and gas transport, thereby considerably enhancing the PEMFC performance. This work provides insights into the two-phase transport behavior in PEMFCs with fMPLs, paving the way for design and development of novel MPLs for high-performance PEMFCs.
ISSN:0017-9310
1879-2189
DOI:10.1016/j.ijheatmasstransfer.2022.123398